JP2020520189A - Base station, RF remote unit and its motherboard, RF daughter card and automatic channel construction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a base station, an RF remote unit and its motherboard, an RF daughter card, and an automatic channel construction method. An RF remote unit includes an RF daughter card and an RF remote unit motherboard. The RF device on the RF daughter card realizes one RF channel, and the IF resource pool on the RF remote unit motherboard is provided with a plurality of IF processing devices that realize the IF channel by being combined. The RF daughter card and the RF remote unit motherboard can be removably connected through the card slot, and the processor on the RF remote unit motherboard can be configured to connect the RF daughter card currently connected in the card slot and the current service configuration. By selecting the necessary RF daughter card based on the information and selecting the corresponding IF processing device from the IF resource pool, the IF channel corresponding to the RF channel realized by the RF daughter card can be realized.

Description

The present invention relates to the field of wireless communication, and specifically to a base station, an RF remote unit and its motherboard, an RF daughter card, and an automatic channel construction method.

A base station is an indispensable constituent element of a wireless communication network, and a conventional base station is generally composed of a baseband processing unit (Building Base band Unit, BBU) and an RF remote unit (Radio Remote Unit, RRU). Has been done. At the same time, as the service aspect continues to expand, a form of a base station such as blind compensation with a small power also appears. In these base station configurations, the relatively fixed feature is that RF devices such as power amplifiers on each RF channel are integrated on a single board, and IF processing devices corresponding to all RF devices are also fixed. Is to be done. Therefore, once a single board is molded, the RF and IF capabilities of the RF remote unit are all fixed. Therefore, when the substrate is processed and molded, the capacity of the RF remote unit is fixed, and when a failure appears in the RF channel or the capacity of the RF channel is insufficient, a part cannot be replaced, The cost of use is high because only the entire single board can be replaced.

Embodiments of the present invention provide a base station, an RF remote unit and its motherboard, an RF daughter card, and a method for automatically constructing a channel, so that the device on the RF remote unit is fixed and the capability is fixed. , At least partially solve the problem of high cost of use.

Embodiments of the present invention provide an RF daughter card including a card body, an RF device provided on the card body, and a daughter card interface. The RF device is electrically connected to the daughter card interface to realize one RF channel. The card body is removably connected to the RF remote unit motherboard through a card slot on the RF remote unit motherboard, and when the card body is connected to the RF remote unit motherboard, the daughter card interface and the RF are connected. A mother board interface on a remote unit motherboard is electrically connected, and the mother board interface is connected to an IF processor for realizing an IF channel on the RF remote unit motherboard.

The embodiment of the present invention further provides an RF remote unit motherboard including a board body, a processor provided on the board body, an IF resource pool, a card slot, and a motherboard interface. The IF resource pool includes a plurality of IF processing devices that combine to realize an IF channel, and the motherboard interface is electrically connected to the IF processing devices in the IF resource pool. The card slot is used for mating connection with the card body of the RF daughter card according to the present invention so that the daughter card interface and the motherboard interface are electrically connected. The processor selects a required RF daughter card based on the RF daughter card currently connected to the card slot and the current service configuration information, and selects a corresponding IF processing device from the IF resource pool. In order to realize the IF channel corresponding to the RF channel realized by the selected RF daughter card.

Embodiments of the present invention further provide an RF daughter card according to the present invention and an RF remote unit including the RF remote unit motherboard according to the present invention. The RF daughter card is removably connected to a card slot on the RF remote unit motherboard, and the daughter card interface is electrically connected to the motherboard interface.

Embodiments of the present invention further provide a base station including a baseband processing unit and an RF remote unit according to the present invention, the RF remote unit being connected to the baseband processing unit. The processor of the RF remote unit motherboard obtains the capability information of the RF daughter card currently connected in the card slot on the board body of the RF remote unit motherboard, and feeds the capability information back to the baseband processing unit. Selecting the required RF daughter card from the RF daughter cards currently connected to the card slot on the board body of the RF remote unit motherboard, based on the service configuration information transmitted from the baseband processing unit; It is provided to realize an IF channel corresponding to the RF channel realized by the selected RF daughter card by selecting the corresponding IF processing device from the IF resource pool of the RF remote unit motherboard. The baseband processing unit is arranged to transmit service configuration information to the processor based on the capability information fed back from the processor.

The embodiment of the present invention further provides a method for automatically constructing a channel of an RF remote unit, obtaining capability information of an RF daughter card currently connected to a card slot on a board body of the RF remote unit motherboard, Feeding back capability information to a baseband processing unit, receiving service configuration information transmitted from the baseband processing unit based on the capability information, and based on the service configuration information, the RF remote unit motherboard It is selected by selecting the required RF daughter card from the RF daughter cards currently connected to the card slot on the board main body of the board and selecting the corresponding IF processing device from the IF resource pool of the RF remote unit motherboard. Implementing an IF channel corresponding to the RF channel implemented by the RF daughter card.

An embodiment of the present invention further provides a computer-readable storage medium having a computer program stored therein, and when the computer program is executed by a processor, the method for automatically constructing a channel of an RF remote unit according to the present invention is provided to the processor. Let it run.

The drawings described herein are provided for a further understanding of the present invention and form a part of this application. The illustrative examples of the present invention and their description are used to understand the present invention, but not to limit the present invention.

FIG. 1 is a structural conceptual diagram of an RF daughter card according to each embodiment of the present invention. FIG. 2 is a structural conceptual diagram of an RF daughter card according to each embodiment of the present invention. FIG. 3 is a structural conceptual diagram of an RF daughter card according to each embodiment of the present invention. FIG. 4 is a structural conceptual diagram of an RF remote unit motherboard according to an embodiment of the present invention. FIG. 5 is a structural conceptual diagram of an IF resource pool according to an embodiment of the present invention. FIG. 6 is a structural conceptual diagram of an RF remote unit motherboard according to an embodiment of the present invention. FIG. 7 is a structural conceptual diagram of an RF remote unit according to an embodiment of the present invention. FIG. 8 is a conceptual flowchart of a method for automatically constructing a channel of an RF remote unit according to an embodiment of the present invention. FIG. 9 is a conceptual flowchart of an automatic channel construction method for a base station according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail by combining specific embodiments.
An RF remote unit according to an embodiment of the present invention includes an RF daughter card and an RF remote unit motherboard. The RF device on the RF daughter card realizes one RF channel, and the IF resource pool on the RF remote unit motherboard is provided with a plurality of IF processing devices that realize the IF channel by being combined. The RF daughter card and the RF remote unit motherboard can be removably connected by a card slot, and the processor on the RF remote unit motherboard can display the RF daughter card currently connected in the card slot and the current service configuration information. Based on this, by selecting the required RF daughter card and selecting the corresponding IF processing device from the IF resource pool, the IF channel corresponding to the RF channel realized by the RF daughter card can be realized. According to the embodiment of the present invention, the RF daughter card for realizing the RF channel can be removed from the RF remote unit motherboard, and the IF resource on the RF remote unit motherboard depends on the specific service and the RF daughter card. Since they can be flexibly combined, it is possible to adapt to various application needs by flexibly changing the RF capability and the IF capability of the RF remote unit. In order to better understand the present invention, an RF daughter card and an RF remote unit motherboard (also referred to as a single board) according to the present invention will be exemplified below.

1 to 3 are structural conceptual diagrams of an RF daughter card according to each embodiment of the present invention, and FIG. 4 is a structural conceptual diagram of an RF remote unit motherboard according to the exemplary embodiment of the present invention.
Referring to FIGS. 1 and 4, the RF daughter card according to the present embodiment includes a card body 11, an RF device 13 provided on the card body 11, and a daughter card interface 12. According to this embodiment, the RF device 13 on one card body 11 is used to realize one RF channel (that is, RF link).

The card body 11 of the RF daughter card according to the present embodiment is detachably connected to the card slot 25 on the RF remote unit motherboard. According to this embodiment, when the card body 11 is connected to the RF remote unit motherboard, the daughter card interface 12 on the card body 11 is electrically connected to the motherboard interface 24 on the RF remote unit motherboard. Since the motherboard interface 24 is connected to the IF processing device for realizing the IF channel by being combined on the RF remote unit motherboard, a connection relationship between the RF channel and the IF channel is established.

Referring to FIGS. 1 and 4, the daughter card interface 12 of the RF daughter card according to the present embodiment may be provided at one end of the card body 11 that is fitted into the card slot 25. The card body 11 can be removably connected to the RF remote unit motherboard by a method of inserting or fitting in the card slot 25. Of course, it is also possible to adopt another method to removably connect. The motherboard interface 24 on the RF remote unit motherboard can be installed directly in the card slot 25. To ensure the reliability and convenience of the contacts, the motherboard interface 24 can be installed directly on the bottom of the card slot 25. When the card body 11 is fitted in the card slot 25, the daughter card interface 12 is electrically connected to the motherboard interface 24 at the bottom of the card slot 25.

It can also be understood that the daughter card interface 12 and the motherboard interface 24 according to the present embodiment can be provided in areas other than the card slot 25 and can be connected to each other by wiring.

According to this embodiment, the RF device 13 on the RF daughter card can realize a transmission RF channel (that is, a transmission RF link) or a reception RF channel (that is, a reception RF link). Also, different RF daughter cards may realize RF channels of different frequency bands, or may realize RF channels of the same frequency band. Therefore, it can be flexibly installed according to specific demand.

Referring to FIG. 2, according to an embodiment of the present invention, the RF device 13 provided on the card body 11 of the RF daughter card includes an amplifier 131, a filter 132, and an antenna 133, which are sequentially connected, and the amplifier 131 is , Daughter card interface 12 can be electrically connected. When the RF device 13 realizes the reception RF channel, the low noise amplifier 131 can be adopted as the amplifier 131. It can be understood that the types of the amplifier 131, the filter 132, the antenna 133, specific functional parameters, and the like can be flexibly set according to specific application situations. For example, as shown in FIG. 3, the daughter card interface 12 of the RF daughter card can be realized by a gold terminal, and when the card body 11 is fitted into the card slot 25 on the RF remote unit motherboard, The gold terminal can be electrically connected to the gold terminal (see FIG. 6) for realizing the motherboard interface 24 at the bottom of the card slot 25, which not only guarantees the reliability of contact, but also the convenience of adaptation. Can also be guaranteed. The RF device 13 can include devices other than the amplifier 131, the filter 132, the antenna 133, and the like shown in the figure, and can be flexibly set according to actual demand.

By the above method, the link board of the RF device 13 is made into a card, and the link of the RF device 13 is divided into RF daughter cards that are functionally independent according to the characteristics of the RF channel. A corresponding card slot 25 is provided in advance on the RF remote unit motherboard. The RF daughter card completes a hard link with the RF remote unit motherboard through the card slot 25, and the RF remote unit motherboard is connected to the RF daughter card already connected by the circuit of the motherboard interface 24 in the card slot 25. By acquiring the number and capability information of each RF daughter card, the RF link and the IF link can be selected and constructed. For ease of understanding, the RF remote unit motherboard will be exemplified below in connection with FIG.

Referring to FIG. 4, the RF remote unit motherboard includes a board body 21, a processor 23 provided on the board body 21, an IF resource pool 22, a card slot 25, and a motherboard interface 24. The IF resource pool 22 includes a plurality of IF processing devices that realize an IF channel by being combined. That is, according to the embodiment of the present invention, there is no limitation on the connection relationship of the IF processing devices in the IF resource pool 22 and the RF channel to which they belong, but according to the actual demand, the necessary IF processing is performed. An IF channel (that is, an IF link) can be realized by flexibly selecting devices and logically combining them.

According to the present embodiment, the motherboard interface 24 is electrically connected to the IF processing device in the IF resource pool 22, and the card slot 25 is matingly connected to the card body 11 of the RF daughter card, so that the RF daughter can be obtained. The card is used to electrically connect the daughter card interface 12 on the card body 11 and the motherboard interface 24.

The processor 23 selects a required RF daughter card based on the RF daughter card currently connected to the card slot 25 on the RF remote unit motherboard and the current service configuration information, and selects the corresponding IF daughter pool from the IF resource pool 22. The processor can be selected to realize the IF channel corresponding to the RF channel realized by the selected RF daughter card, and the automatic construction of the RF channel and the IF channel can be realized.

According to the present embodiment, the IF processing device includes a digital-analog converter, an analog-digital converter, a digital predistortion processor, a peak clipping device, an interpolation filter, a numerical control oscillator, a digital up converter, and a digital down converter. (But not limited to). It is possible to flexibly set what kind of apparatus is included and what kind of apparatus is selected according to actual demand.

According to this embodiment, the IF processing devices in the IF resource pool 22 are interconnected by an interconnect selection register, that is, after forming basic unit resource pools of different types and selectively interconnected, The interconnection selection register is dynamically configured by software to realize the selective interconnection of devices on the signal path to realize the automatic construction process of the IF channel. Such selective interconnection of general-purpose resources can be realized by various methods such as a multiplexer or a look-up table (Look-Up Table, LUT). Digital IF designs can be implemented using FPGA or ASIC methods. Hereinafter, the IF resource pool according to the embodiment of the present invention will be described by taking an interpolation filter, a numerically controlled oscillator, a peak clipping device, and a digital predistortion processor resource unit as an example.

FIG. 5 is a structural conceptual diagram of an IF resource pool according to an embodiment of the present invention.
As shown in FIG. 5, each basic unit is arranged in an array according to its type, and the basic units in the array are interconnected by a selection logic unit LUT.
The software configures the routing configuration register interface, and the input signal stream is in the first stage any filter unit from the filter resource pool, any numerically controlled oscillator from the numerically controlled oscillator resource pool, any peak from the peak clipping device resource pool. By selecting any digital predistortion processor from the clipping device, digital predistortion processor resource pool, a logical virtual IF channel can be constructed and the IF signal processing process can be completed. In the same way, the construction and signal processing of other logical virtual channels can be completed. Software can maintain and guarantee the state and mutual exclusion management of each base unit resource in the resource pool when setting the routing configuration register.

At least two card slots 25 may be provided on the board body 21 of the RF remote unit motherboard, and at least two motherboard interfaces 24 may be provided accordingly. As shown in FIG. 6, the card slot 25 and the motherboard interface 24 can be provided in a one-to-one correspondence, and the motherboard interface 24 can be provided at the bottom of the card slot 25. This allows multiple different RF daughter cards to be connected simultaneously to provide multiple RF channels and corresponding IF channels to meet various service needs.

The processor 23 on the RF remote unit motherboard determines the required RF daughter based on the current service configuration information (eg, from the baseband processing unit) and the capability information of the RF daughter card currently connected in the card slot 25. An IF channel is realized by selecting a card, determining the required IF processing device and the connection relationship between each IF processing device, arranging the interconnection selection registers accordingly, and connecting each IF processing device. It can be used for

The processor 23 on the RF remote unit motherboard knows in which card slot 25 the RF daughter card is connected by the motherboard interface 24, that is, obtains each RF daughter card currently connected on the RF remote unit motherboard. Furthermore, the capability information of these RF daughter cards can be acquired, and the acquired capability information of the RF daughter card can be reported to the baseband processing unit. The baseband processing unit knows the actual capabilities of the RF remote unit and uses this as a constraint for subsequent cell construction so that the cells constructed from the background do not exceed the physical support capabilities of the RF remote unit. Can be guaranteed.

According to an embodiment of the present invention, the RF daughter card capability information includes (but is not limited to) RF remote unit frequency band capability, RF remote unit channel capability, RF remote unit carrier coupling capability, and the like. For example, if the RF remote unit supports the F frequency band, dual channels, and supports up to two 10M carriers on each channel, enter this capability in the message body in the information body and then perform inter-board communication. To the baseband processing unit in the form of.

As shown below, Table 1 shows the frequency band capability table.

Table 2 shows the RF channel capability table as follows.

As shown below, Table 3 shows a carrier binding capacity table.

The cell information table is shown in Table 4 as follows.

As shown below, Table 5 shows a frequency point information table.

In this way, the baseband processing unit sends the actual service configuration information to the RF remote unit according to the capability information of the RF remote unit in the service initial configuration stage (for example, when the cell is first configured). The RF remote unit is capable of satisfying the service configuration according to the actual service configuration information status transmitted from the baseband processing unit, and the corresponding IF processing device and each IF processing device in the IF resource pool 22. Connection relationship information (also referred to as the routing information of the IF subsystem basic unit) is analyzed, and the routing information is arranged in the basic IF subsystem by the routing configuration register interface. The basic IF subsystem dynamically selects a necessary IF processing device (that is, a basic unit) from the IF resource pool 22 according to the routing information, and completes the topology connection between the basic units, thereby realizing the actual background. Build the IF physical links needed to satisfy the configuration and complete the process of building the entire RF link (eg, in the initial configuration stage). In principle, there can be many choices for the routing method, which can be chosen according to the principle that topological connections are simple. The selection algorithm can be implemented by software. The specific algorithm and implementation method are omitted here.

According to this embodiment, the processor 23 on the RF remote unit motherboard can generate new routing information according to the changed service configuration information at the background service changing stage (cell addition or deletion). Based on the new routing information, the basic digital IF subsystem determines the IF subsystem functional units already built on the physical channel, the new attribution of the basic units in the unbuilt IF resource pool 22 and their topological connection relationships. The construction of the IF link that can dynamically adjust and satisfy the changed service is completed. At this stage, the construction of the IF basic functional unit can be done so as to satisfy the RF capability preferentially and then the principle of simple topology connection. The principle selection algorithm can be designed by software.

Further, during the operation of the RF daughter card, the processor 23 on the RF remote unit motherboard can also dynamically monitor the in-position status and failure status of the RF daughter card on the RF remote unit motherboard card slot 25. If it is detected that an RF daughter card has been removed from the card slot 25 (ie, reduced in number), or any RF daughter card has failed (eg, RF device 13 has failed), the processor 23 will , Analyze if there is another vacant RF daughter card unit as a spare. If there is a spare RF daughter card resource, a new IF routing is created and the spare RF daughter card is used to reconstruct the IF link corresponding to the lost or damaged RF daughter card. If there is no spare RF daughter card resource, it will report an abnormal warning alarm to the device to realize auto-build hot swap after RF remote unit RF daughter card failure. Also, if it is detected that the number of RF daughter cards has increased or that one of the board cards has changed from a failed state to an available state, the processor 23 collects and re-stats RF capability information, and a message displays the baseband. It can be reported to the processing unit to realize the dynamic expansion of the capacity of the RF remote unit, which is more suitable for each application.

FIG. 7 is a structural conceptual diagram of an RF remote unit according to an embodiment of the present invention.
Embodiments of the present invention provide an RF remote unit including an RF daughter card and an RF remote unit motherboard. The RF daughter card is removably connected to a card slot 25 on the RF remote unit motherboard, and the daughter card interface 12 of the RF daughter card is electrically connected to the motherboard interface 24 of the RF remote unit.

The processor 23 on the RF motherboard unit selects a necessary RF daughter card based on the RF daughter card currently connected in the card slot 25 and the current service configuration information, and performs the corresponding IF processing from the IF resource pool 22. The device is selected to realize an IF channel corresponding to the RF channel realized by the selected RF daughter card.

It can be understood that a plurality of card slots 25 can be provided on the motherboard of the RF unit in this embodiment, and the IF processing device of the IF resource pool 22 can support a plurality of RF channels (that is, RF links). .. Different types and different capabilities of RF daughter cards can be flexibly mounted on the RF remote unit motherboard according to actual demand. For example, referring to the RF remote unit shown in FIG. 7, the RF daughter card and the RF remote unit motherboard are connected by a gold terminal interface, and both are detachably connected by a card slot 25. However, it can be understood that the connection method is not limited to the removable connection of the card slot 25. In FIG. 7, the devices are distinguished according to the digital-analog (DA)/analog-digital (AD) of the RF link. The circuit near the end of the antenna 133 after the DA on the transmission path and the circuit near the end of the antenna 133 before the AD on the reception path are laid out together, that is, integrated into an RF daughter card. A hardware connection interface is provided on one side. At the same time, the circuit including the side before the DA on the transmission path, which is logically close to the optical port of the DA, and the circuit including the side after the AD on the receive path, which is logically close to the baseband, are laid out together, That is, the RF remote unit motherboard (also referred to as a digital motherboard) is provided, and N slot interfaces are provided on one side of the motherboard for hardware connection with the RF daughter card. The slot interface between the RF daughter card and the digital motherboard can be any type of hardware interface that can meet the demands of electrical connection and coupling, such as the gold terminal slot interface shown in FIG. May be.

When designing a logical IF, some basic units (that is, an IF processing device such as an interpolation filter, a numerically controlled oscillator, a peak clipping device, a digital predistortion processor, etc.) in the entire IF carrier processing are classified according to types. When laid out in an array, the basic units in the array are interconnected by select logic units, i.e., forming a basic unit resource pool that can be of different types and selectively interconnected. Then, the interconnection selection register is dynamically placed by software to complete the selective interconnection of the devices on the signal path, thereby realizing the automatic channel construction process. Here, the selective interconnection of the general-purpose resources can be realized by various methods such as a multiplexer and a look-up table. As a digital IF design method, a method such as FPGA or ASIC can be adopted. The software configures the routing configuration register interface, and the input signal stream can initially select any filter unit in the subsequent filter resource pool. The state and mutual exclusion management of basic unit resources in the resource pool can be maintained and guaranteed by software when configuring the routing registers.

FIG. 8 is a conceptual flowchart of a method for automatically constructing a channel of an RF remote unit according to an embodiment of the present invention.

According to the embodiment of the present invention, the method for automatically constructing the channel of the RF remote unit may include steps S801 to S803.

In step S801, the capability information of the RF daughter card currently connected to the card slot 25 on the board body 21 is acquired, and the capability information is fed back to the baseband processing unit.

During the power-on stage of the RF remote unit motherboard, the processor 23 on the RF remote unit motherboard obtains the number and type of RF daughter cards currently inserted on the motherboard through the card slot 25 interface. By estimating its maximum RF capability that can be supported, and notifying this capability information in the form of a message to the baseband processing unit, which in turn recognizes the actual capability of the RF remote unit by As a constraint for subsequent cell construction, ensure that the cells constructed from the background do not exceed the physically supportable capacity of the RF remote unit.

In S802, the service configuration information transmitted based on the capability information of each RF daughter card is received from the baseband processing unit.

S803: Based on the service configuration information, select the required RF daughter card from the currently connected RF daughter cards in the card slot 25 on the board main body 21 and select the corresponding IF processing device from the IF resource pool 22. Then, the IF channel corresponding to the RF channel realized by the selected RF daughter card is realized.

At the stage of service initial configuration (for example, when configuring a cell for the first time), the RF remote unit can satisfy the service configuration according to the actual service configuration information transmitted from the baseband processing unit. , And the connection relation information of the basic unit in the IF resource pool (also referred to as the routing information of the IF subsystem basic unit. The abbreviation is the routing information), and it is arranged in the basic digital IF subsystem by the routing configuration register interface. To do. The basic digital IF subsystem dynamically selects the required basic unit from the IF digital resource pool according to the routing information, completes the topology connection between each basic unit, and completes the IF necessary for satisfying the actual background configuration. Building the physical link completes the initial RF link entire link building process. At this stage, in principle, there may be a plurality of selections in the routing selection, and the selection can be made based on the principle that the topology connection is simple. The selection algorithm can be realized by software.

According to an embodiment of the present invention, at this stage, the RF remote unit has the capability of the RF link on the link (including, for example, RF remote unit frequency band capability, RF remote unit channel capability, RF remote unit carrier coupling capability). Based on, the frequency band supported by the RF remote unit, the channel-to-frequency band mapping relationship, the combination of carrier bandwidth configurations supported on the channel, etc. are reported to the baseband resource pool in the form of inter-board messages. The baseband resource pool transmits the cell information and the frequency point information configured in the background within the capability range to the RF remote unit based on the capability information information reported by the RF remote unit. The RF remote unit analyzes the antenna group information and the number of carriers information in the cell information transmitted by the baseband resource pool, and the center frequency point information and the carrier baseband information in the frequency point information, so that the topology connection is the simplest. According to the constraint method that there is something, information (that is, routing information) for determining the topological connection relationship of various basic units in the digital resource pool is dynamically generated. For the same configuration, there are multiple topological connections of different base units, ie different routing information. Depending on the specific service situation, 1) the topology connection is simple, 2) the already existing topology is invariant, 3) the whole transition, etc. To generate the final routing information. The constraint algorithm here can be explained as follows. That is, the number of each basic unit in the IF resource pool 22 that is selectively connected to a specific RF link must be the closest resource number without exception, under the constraint that topology connection is simple. Under the constraint that the topology is invariant, in the newly added routing information, the related IF resource must be in an unused state before being constructed. Under the constraint condition that the entire resource is transferred, the topology connection of each IF resource in the IF resource pool 22 is not changed, and the IF resource pool 22 is forcibly connected to the designated RF resource.

Through the routing configuration register interface, the true value corresponding to the final routing information is set in the FPGA subsystem, and then the related service parameter configuration operation is performed, and the initial automatic uplink/downlink automatic construction process of the overall RF remote unit. To complete. During the power up phase, the processor 23 on the motherboard acquires the currently supported RF capabilities (including, for example, RF remote unit frequency band capability, RF remote unit channel capability, RF remote unit carrier coupling capability). For example, if the RF remote unit supports the F frequency band and dual channels, and supports up to two 10M carriers for each channel, after inputting this capability in the information body in the message format, the inter-board communication format Can inform the baseband processing unit. The baseband processing unit knows the actual capacity of the RF remote unit as described above, and uses this as a constraint for subsequent cell construction, and the cell composed of the background does not exceed the physically supportable capacity of the RF remote unit. Can be guaranteed. The input results are shown in the table below.

Table 6 shows an input example of the frequency band capability table (Table 1).

Table 7 shows an input example of the RF channel capability table (Table 2) for channel 0.

Table 8 shows an input example of the RF channel capability table (Table 2) of channel 1.

Table 9 shows an input example of the table (Table 3) of the carrier combining ability of channel 0.

Table 10 shows an input example of the table (Table 3) of the carrier coupling ability of channel 1.

With FIG. 8, it is possible to complete the service configuration at the time of initial power-on and the automatic construction process of the RF channel and the IF channel. For example, in the background service initial configuration stage (e.g., when configuring a cell for the first time), the RF remote unit uses the antenna group, the number of carriers, and the center frequency in the actual cell information and frequency point information transmitted from the baseband processing unit. Based on points, carrier bandwidth, etc., we analyze routing information that satisfies the constraint that topology connection is the simplest. For example, in the acquired cell information and frequency point information, the antenna group field information is 1, the carrier number field information is 1, the center frequency point is 18805 (unit is 100 kz), and the carrier bandwidth is 20 M (unit is bps). In this case, based on this, mapping is performed so that carriers having a bandwidth of 10 M and a frequency point of 18805 (unit is 100 KZ) are respectively constructed on channels 0 and 1 on the RF remote unit, and then the topology connection is most The following routing information can be obtained subject to the limitation of simplicity. For example, in the IF resource pool 22, the differential filter with the number 1 in the interpolation filter resource pool is selectively connected to the numerically controlled oscillator functional unit with the number 1 in the numerically controlled oscillator resource pool, and the peak clipping device is further provided. Channels are selectively connected to the peak clipping device functional unit numbered 1 in the resource pool and further to the digital predistortion processor functional unit numbered 1 in the digital predistortion processor resource pool. Selectively connect to 0 RF resources. Similarly, the differential filter with the number 2 in the interpolation filter resource pool is selectively connected to the numerically controlled oscillator functional unit with the number 2 in the numerically controlled oscillator resource pool, and the number in the peak clipping device resource pool is further connected. Selectively connect to the peak clipping device functional unit of 2 and further to the digital predistortion processor functional unit of number 2 in the digital predistortion processor resource pool, and then to the RF resource of channel 1. Connect selectively. Then, the true value corresponding to such routing information is set in the IF subsystem of the FPGA, and the IF subsystem completes the actual physical connection according to the instruction of the true value, thereby performing the initial construction process of the RF remote unit. Complete.

In the present embodiment, the constructed channel can be dynamically adjusted according to the change in the service configuration, the in-position state of the RF daughter card, and the operating state of the RF daughter card.

According to the embodiment of the present invention, when the processor 23 needs to update the IF processing device when changing the service configuration information, the processor 23 requires the IF processing device and the inter-IF processing devices according to the changed service configuration. The IF channel is realized by re-establishing the connection relation of (1), newly configuring the corresponding interconnection selection register, and connecting each of the IF processing devices. Of course, when it is necessary to change the IF processing device when changing the service configuration information, if it is determined that the service demand can be satisfied even by using the current RF channel and IF channel, no change is required.

According to the embodiment of the present invention, after the background service configuration is changed, the RF remote unit may receive the antenna group information, the frequency point information, the number of carriers, the carrier bandwidth, and the current information in the cell information transmitted from the background. By re-analyzing whether or not the functional block in the IF resource pool 22 is empty, new IF routing information is generated and converted into a true value of the routing information, and the basic IF subsystem is set to the IF subsystem logical resource pool. Complete the reconstruction of the basic unit topology to achieve the dynamic realignment of device links. For example, if one more 10M carrier is added to each channel based on the above example, the topology on the link that has not changed is unchanged and is newly generated based on the changed configuration information. New routing information can be generated that satisfies the constraint that topological connections are the simplest. That is, in the IF resource pool 22, the differential filter with the number 1 in the interpolation filter resource pool is selectively connected to the functional unit of the numerically controlled oscillator with the number 1 in the numerically controlled oscillator resource pool, and the peak clipping device is further provided. Channels are selectively connected to the peak clipping device functional unit numbered 1 in the resource pool and further to the digital predistortion processor functional unit numbered 1 in the digital predistortion processor resource pool. 0 RF resource to be selectively connected and used as the first 10M carrier for processing channel 0. The differential filter numbered 3 in the interpolation filter resource pool is selectively connected to the numerically controlled oscillator functional unit numbered 3 and further to the peak clipping device functional unit numbered 3 in the peak clipping device resource pool. And further connect to the digital predistortion processor functional unit numbered 3 in the digital predistortion processor resource pool, and then selectively connect to the RF resource of channel 0 to process channel 0. Used as the second 10M carrier. Interpolation filter The differential filter numbered 2 in the resource pool is selectively connected to the numerically controlled oscillator functional unit numbered 2 in the numerically controlled oscillator resource pool, and the peak numbered 2 peak in the peak clipping device resource pool is further connected. Selectively connected to the clipping device functional unit, and further selectively connected to the digital predistortion processor functional unit numbered 2 in the digital predistortion processor resource pool, and then further selectively connected to the RF resource of channel 1. Then, channel 1 is used as the first 10M carrier for processing. The differential filter number 4 in the interpolation filter resource pool is selectively connected to the numerically controlled oscillator functional unit number 4 and further to the peak clipping device functional unit number 4 in the peak clipping device resource pool. To the digital predistortion processor functional unit number 4 in the digital predistortion processor resource pool, and then selectively connect to the RF resource of channel 1 to process channel 1. Used as the second 10M carrier. Then, the true value corresponding to this routing is set in the underlying FPGA by the routing configuration register interface. The FPGA sequentially and dynamically adjusts the new attachment of the basic unit in the IF resource pool 22 and its topological connection relationship, and completes the construction of the IF link that can satisfy the changed service.

The processor 23 is also used during operation of the RF daughter card to monitor the RF daughter card for removal from the card slot 25 and/or for failure of the RF device 13 on the RF daughter card. When the detachment or the failure occurs, it is determined whether or not the vacant RF daughter card is connected to the card slot 25 of the board body 21. If an empty RF daughter card is present, select one of the empty RF daughter cards and the required IF processor and connection between each IF processor for the selected empty RF daughter card. The IF channel is realized by establishing the relationship, configuring the corresponding interconnection selection register, and connecting each IF processing device.

According to an embodiment of the present invention, during the operation of the RF device, the monitoring software of the processor 23 on the motherboard dynamically monitors the status of the RF link. If it is detected that the RF link is faulty, the processor 23 analyzes whether there is another free RF link that can be used as a spare. If a spare RF link exists, a new IF routing is newly created, and the spare RF link is used to newly construct an IF link corresponding to the damaged RF link. If there are no RF channel resources available as spares, the system reports a device malfunction warning alarm.

For example, an abnormality occurs in the RF link of channel 0, and at this time, the corresponding routing information is "the differential filter with the number 1 in the interpolation filter resource pool, the numerically controlled oscillator with the number 1 in the numerically controlled oscillator resource pool. Selectively connected to the functional unit and further to the peak clipping device functional unit number 1 in the peak clipping device resource pool, and further to digital predistortion number 1 in the digital predistortion processor resource pool. After selectively connecting to the processor functional unit, it is further selectively connected to the RF resource of channel 0." If the RF link of channel 1 is normal and empty, the IF routing information is the entire RF. Move it to resource 1. Therefore, the final routing information is: "The differential filter numbered 1 in the interpolation filter resource pool is selectively connected to the numerically controlled oscillator functional unit numbered 1 in the numerically controlled oscillator resource pool, and the peak clipping device Channels are selectively connected to the peak clipping device functional unit numbered 1 in the resource pool and further to the digital predistortion processor functional unit numbered 1 in the digital predistortion processor resource pool. To selectively connect to one RF resource”.

If there is no free RF link available at this time, the routing information is not updated and the related failure information is collected and channel anomaly is reported to the baseband resource pool.
The RF remote unit provided by this embodiment can flexibly set the IF resource on the motherboard according to the current RF daughter card and service demand, so that the IF basic unit resource on the motherboard can be shared by each RF channel. Therefore, the idle resources are greatly multiplexed, and the resource utilization rate is improved. In the process of use, if a certain RF channel fails and needs to be replaced (for example, a power amplifier unit fails) or the capacity cannot meet the demand, the old RF daughter card is removed and a new RF daughter card is inserted. It only needs to be plugged in, and hot swapping for failure of the RF device can be realized without turning off the power of the entire machine, which not only increases the flexibility of use but also significantly reduces the cost of use. When the functions of the RF remote unit and the baseband processing unit are unchanged, to expand the capacity, simply insert the newly added RF daughter card into the card slot, and after restarting the entire machine, the capacity will be self-reliant. It can be adapted and self-expanding (this kind of expansion scheme is static expansion). Considering that the capability of the baseband processing unit side is affected, the RF capability is expanded without reducing the power of the RF remote unit, that is, the RF capability of the RF remote unit is dynamically expanded. Good.

FIG. 9 is a conceptual flowchart of an automatic channel construction method for a base station according to an embodiment of the present invention.

A base station provided by an embodiment of the present invention includes a baseband processing unit and an RF remote unit of the present invention. The RF remote unit is connected to the baseband processing unit and serves as an interface for specifically connecting the two. , OPT interface and various connection interfaces can be adopted.

The processor 23 of the RF remote unit acquires the capability information of the RF daughter card currently connected to the card slot 25 on the motherboard board main body 21, feeds it back to the baseband processing unit, and transmits it from the baseband processing unit. Based on the service configuration information, select the required RF daughter card from the RF daughter cards currently connected to the card slot 25 on the board body 21, select the corresponding IF processing device from the IF resource pool 22, The IF channel corresponding to the RF channel realized by the selected RF daughter card is realized.

The baseband processing unit sends service configuration information to the RF remote unit processor 23 based on the RF remote unit capability information and the current service demand.

In this embodiment, the base station can also dynamically adjust the established channel according to the change in service configuration, the in-position state of the RF daughter card, and the operating state of the RF daughter card. The automatic channel construction method of the base station shown in FIG. 9 includes steps S901 to S911.

In S901, the uplink/downlink paths of the RF remote unit are laid out on the daughter card (that is, the RF daughter card) on a channel-by-channel basis with the AD/DA as a boundary, and the circuit near the baseband side is digital. It is laid out on a motherboard (that is, an RF remote unit motherboard), and N gold terminal slots are provided on the motherboard, and the motherboard and the daughter card can be physically and electrically connected by the gold terminal slots.

In step S902, the IF basic unit (including the interpolation filter, the numerically controlled oscillator, the peak clipping device, the digital predistortion processor, etc.) is collectively designed into a general-purpose resource pool, and the routing configuration register interface of the IF subsystem is configured by software. Realize the dynamic selective connection of basic units in the resource pool.

In step S903, at the power-on stage of the digital motherboard, the number and type of daughter cards connected to the motherboard are acquired by the card slot 25, the maximum RF capability thereof is analyzed, and the result is reported to the baseband processing unit in the form of a message. As a constraint on the background service configuration, that is, the background configuration should not exceed the maximum RF capability of the daughter card.

In S904, in the initial configuration stage of the service, the RF remote unit generates the routing information by analyzing the service information, and places the routing information in the IF subsystem by the routing configuration register interface to dynamically build the IF link, and The connection between the IF circuit and the RF daughter card is completed, and then the processing of service information is completed.

In step S905, when the service configuration changes, the dynamic adjustment of the link resource is completed by regenerating and arranging the routing information according to the new service information.
In step S906, during operation of the RF device, the motherboard processor 23 periodically monitors the status of the RF daughter card and observes whether a failure or a decrease in the daughter card has occurred, and the failure or the decrease in the number. If no has occurred, the process proceeds to S907, and if not, the process proceeds to S909.

In S907, it is confirmed whether or not the number of daughter cards has increased. If not, the process proceeds to S906, and if not, the process proceeds to S908.

In S908, the message interface reports an increase in RF power to the background, dynamically updates the constraints of the background configuration, and dynamically expands the RF power.

In S909, it is checked whether or not there is another vacant RF daughter card. If yes, the process proceeds to S910, and if not, the process proceeds to S911.
In S910, a new routing configuration table is generated, the routing configuration is automatically updated, link rebuilding is completed, and a hot standby for a failure is realized.

In S911, an RF daughter card failure alarm is reported.
According to the base station of this embodiment, the RF device in the RF remote unit can have a link board/card design. The link of a conventional fixed RF device is physically separated from the digital board according to its function, and is connected to the IF link on the digital board by an interface such as a slot. Further, by constructing a resource pool of the IF basic unit on the motherboard, the basic unit is a general-purpose resource without predetermining which specific link or specific carrier of the RF remote unit the IF resource belongs to. It is integrated into the resource pool and managed collectively. Prior to being dynamically built, each base unit does not belong to any actual link or carrier on any RF remote unit.

The actual uplink/downlink is dynamically created based on the resources of the RF daughter card and the basic unit of the IF link. During the initial service configuration phase of the system, the required basic unit is dynamically selected from the IF link pool according to the daughter card unit data already existing on the system and the corresponding capability of the daughter card unit, and the topology of each basic unit is selected. By completing the connection relationship and the initialization operation of each associated device, the dynamic initial construction of each RF link can be completed.

When the background service configuration changes or the number or type of RF link daughter cards changes, the topological connections of the base units of the resource pool are adjusted in real time so that the link self-adaptation of active RF remote units can be achieved. Can be completed. Dynamically monitor the changing status of the daughter card of the RF remote unit, or dynamically reconfigure the topology connection of the IF basic unit in real time according to the changing status of the background configuration, and Completing the dynamic adjustment of the downlink will complete the hot standby of failure and the dynamic expansion of RF capability to some extent.

Each module or each step of the embodiments of the present invention described above can be realized by using a general computing device, which may be centralized in a single computing device or distributed in a network of multiple computing devices. Alternatively, it may be realized by a program code executable by a computer to be stored in a computer storage medium (ROM/RAM, magnetic disk, optical disk) and executed by the computer. And in some cases, the illustrated or described steps may be performed out of the order noted above, or they may each be fabricated in an integrated circuit module, or multiple modules or steps therein may be combined into a single integrated circuit module. It can be clearly understood by those skilled in the art that the circuit module may be manufactured and realized. Therefore, the present invention is not limited to any particular combination of hardware and software.

The above content is a more detailed description of the present invention in which specific embodiments are combined, and the specific implementation of the present invention is not limited to these descriptions. Persons of ordinary skill in the art may make various inferences or substitutions without departing from the concept of the present invention, all of which are regarded as the claims of the present invention.

Claims (13)

An RF daughter card including a card body, an RF device provided on the card body, and a daughter card interface,
The RF device is electrically connected to the daughter card interface to realize one RF channel,
The card body is removably connected to the RF remote unit motherboard via a card slot on the RF remote unit motherboard, and when the card body is connected to the RF remote unit motherboard, the daughter card interface is the RF. An RF daughter card, which is electrically connected to a motherboard interface on a remote unit motherboard, the motherboard interface being connected to an IF processing device for implementing an IF channel on the RF remote unit motherboard. The daughter card interface is provided at one end of the card body that is fitted in the card slot, and when the card body is fitted in the card slot, the daughter card interface is a bottom portion of the card slot. The RF daughter card of claim 1, electrically connected to the motherboard interface of. The RF daughter card of claim 1 or 2, wherein the RF device includes an amplifier, a filter, and an antenna connected in sequence, the amplifier being electrically connected to the daughter card interface. An RF remote unit motherboard including a board body, a processor provided on the board body, an IF resource pool, a card slot, and a motherboard interface,
The IF resource pool includes a plurality of IF processing devices that realize an IF channel by being combined, and the motherboard interface is electrically connected to the IF processing devices in the IF resource pool.
The card slot is used for mating connection with the card body of the RF daughter card according to claim 1, wherein the daughter card interface and the motherboard interface are electrically connected. The
The processor selects a required RF daughter card based on the RF daughter card currently connected to the card slot and the current service configuration information, and selects a corresponding IF processing device from the IF resource pool. An RF remote unit motherboard provided to realize an IF channel corresponding to the RF channel realized by the selected RF daughter card. At least two card slots and at least two motherboard interfaces are provided on the board body, and the at least two card slots and the at least two motherboard interfaces have a one-to-one correspondence and the at least two motherboard interfaces. The RF remote unit motherboard according to claim 4, wherein each is provided on a bottom portion of the at least two card slots. 5. The IF processing device according to claim 4, wherein the IF processing device includes a digital-analog converter, an analog-digital converter, a digital predistortion processor, a peak clipping device, an interpolation filter, a numerically controlled oscillator, a digital up converter, and a digital down converter. RF remote unit motherboard. IF processing devices in the IF resource pool are interconnected by an interconnect selection register,
The processor is
Based on the current service configuration information and the capability information of the RF daughter card currently connected in the card slot, the required RF daughter card is selected, and the necessary IF processing device and the connection relationship between each IF processing device are selected. To confirm
5. The interconnection selection register is arranged to connect the respective IF processing devices so as to realize an IF channel corresponding to an RF channel realized by the selected RF daughter card. 6. The RF remote unit motherboard according to any one of 6 above. An RF daughter card according to any one of claims 1 to 3, and an RF remote unit motherboard according to claim 4,
The RF remote unit, wherein the RF daughter card is detachably connected to a card slot on the RF remote unit motherboard, and the daughter card interface is electrically connected to the motherboard interface. IF processing devices in the IF resource pool of the RF remote unit motherboard are interconnected by an interconnect selection register,
The processor further comprises
When the service configuration information is changed and the IF processing device needs to be updated, the necessary IF processing device and the connection relationship between each IF processing device are re-established according to the changed service configuration, and the interconnection selection register is re-established. The RF remote unit according to claim 8, wherein the RF remote unit is provided so as to realize an IF channel corresponding to the changed service configuration by configuring and connecting the respective IF processing devices. At least two card slots and at least two motherboard interfaces are provided on a board body of the RF remote unit motherboard, and the at least two card slots and the at least two motherboard interfaces have a one-to-one correspondence. At least two motherboard interfaces are provided at the bottom of each of the at least two card slots,
The processor further comprises
During operation of the RF daughter card, monitor whether the RF daughter card has left the card slot and/or the RF device on the RF daughter card has failed,
When the card slot is removed or a failure occurs, it is determined whether or not an empty RF daughter card is connected to the card slot of the board body,
If an empty RF daughter card is connected, select one empty RF daughter card and determine the necessary IF processor and the connection relationship between each IF processor based on the selected empty RF daughter card. And, arranging the interconnection selection register to connect each of the IF processing devices so as to realize an IF channel corresponding to the RF channel realized by the selected vacant RF daughter card. 9. The RF remote unit according to item 9. A base station comprising a baseband processing unit and an RF remote unit according to any one of claims 8 to 10, wherein the RF remote unit is connected to the baseband processing unit,
The processor of the RF remote unit motherboard is
Acquiring capability information of the RF daughter card currently connected to the card slot on the board body of the RF remote unit motherboard, and feeding back the capability information to the baseband processing unit,
Based on the service configuration information transmitted from the baseband processing unit, the required RF daughter card is selected from the RF daughter cards currently connected to the card slot on the board body of the RF remote unit motherboard, and the RF By selecting the corresponding IF processing device from the IF resource pool of the remote unit motherboard, it is provided so as to realize the IF channel corresponding to the RF channel realized by the selected RF daughter card,
The baseband processing unit,
A base station arranged to transmit service configuration information to the processor based on the capability information fed back from the processor. A method for automatically constructing a channel of an RF remote unit, comprising the RF remote unit according to claim 8.
Acquiring capability information of the RF daughter card currently connected in a card slot on the main body of the RF remote unit motherboard, and feeding back the capability information to the baseband processing unit;
Receiving service configuration information transmitted from the baseband processing unit based on the capability information;
Based on the service configuration information, a required RF daughter card is selected from the RF daughter cards currently connected to the card slot on the main body of the RF remote unit motherboard, and is selected from the IF resource pool of the RF remote unit motherboard. A method of automatically constructing a channel of an RF remote unit, comprising: selecting an associated IF processing device to realize an IF channel corresponding to the RF channel realized by the selected RF daughter card. A computer-readable storage medium having a computer program stored thereon, which causes the processor to execute the method for automatically constructing a channel of an RF remote unit according to claim 12, when the computer program is executed by the processor.

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